CN102289267A - Heat radiation device of memory - Google Patents

Abstract

The invention discloses a heat radiation device of a memory. The heat radiation device is applied to a memory and used for radiating heat of the memory. The heat radiation device of the memory comprises two heat conducting plates and one heat radiation element connected with two heating conducting plates; the heat radiation element comprises a heat radiation soleplate and a plurality of heat radiation fins extending from the heat radiation soleplate; an air channel for guiding air flow is formed between two adjacent heat radiation fins; two heat conducting plates are arranged at two relative ends of the heat radiation soleplate, so that an accommodating space for holding the memory is formed among the two heat conducting plates and the heat radiation soleplate; a heat conducting medium is attached at the inner side of each heat conducting plate and the distance between the heat conducting mediums on the inner sides of two heat conducting plates is just equal to the thickness of the memory, so that the heat radiation device is installed on the memory and then the heat of the memory is conducted to the heat radiation fins via the heat conducting medium. According to the invention, the heat radiation efficiency of the memory is improved.

Description

The storer heat abstractor

Technical field

The present invention relates to a kind of storer heat abstractor.

Background technology

During the computer running, storer constantly produces heat as a pyrotoxin, and storer is overheated can't to turn round in order not cause, and storer is dispelled the heat to be necessary.Traditional way mainly is that the side at storer attaches the heat dissipation problem that a heat radiator solves storer, but, after adopting traditional way that storer is dispelled the heat, analog simulation finds, in that to give described storer certain when distinguished and admirable, the temperature of described storer is still very high, still can't solve the heat dissipation problem of storer.

Summary of the invention

In view of above content, be necessary to provide a kind of storer heat abstractor, to solve the heat dissipation problem of storer.

A kind of storer heat abstractor, comprise two heat-conducting plates and a radiating piece that is connected with described two heat-conducting plates, described radiating piece comprises a radiating bottom plate and some radiating fins of being located on the described radiating bottom plate, form the distinguished and admirable air channel of a guiding between every two adjacent radiating fins, described two heat-conducting plates are arranged on the relative two ends of described radiating bottom plate, thereby the receiving space of described storer is accommodated in formation one between described two heat-conducting plates and described radiating bottom plate, the inboard heat-conducting medium that attaches of each heat-conducting plate, distance between the inboard heat-conducting medium of described two heat-conducting plates just equals the thickness of described storer, conducts to described radiating fin with the heat that is installed in the described storer in back on the described storer at described heat abstractor by described heat-conducting medium.

Storer heat abstractor of the present invention is compared to prior art, described storer heat abstractor comprises two heat-conducting plates and a radiating piece that is connected with described two heat-conducting plates, described radiating piece comprises a radiating bottom plate and some by the extended radiating fin of described radiating bottom plate, form the distinguished and admirable air channel of a guiding between every two adjacent radiating fins, thereby improved radiating efficiency, solved the heat dissipation problem of described storer described storer.

Description of drawings

Below in conjunction with accompanying drawing and better embodiment the present invention is described in further detail:

Fig. 1 is that storer heat abstractor better embodiment of the present invention is applied to the exploded view on the storer that is plugged in the memory bank.

Fig. 2 is the assembly drawing of storer heat abstractor among Fig. 1.

Fig. 3 is a plurality of storer heat abstractor user mode reference diagrams.

The main element symbol description

Storer 10

Heat-conducting plate 20

Radiating piece 30

Radiating bottom plate 32

Radiating fin 34

Air channel 36

Memory bank 40

Heat abstractor 100

Embodiment

See also Fig. 1 and Fig. 2, storer heat abstractor 100 of the present invention is applied to a storer 10 so that described storer 10 is dispelled the heat.The better embodiment of described storer heat abstractor 100 comprises two heat-conducting plates 20 and a radiating piece 30 that is connected with described two heat-conducting plates 20.Each heat-conducting plate 20 is rectangle, and the inboard of each heat-conducting plate 20 attaches a heat-conducting medium (not shown) with heat conduction efficiency, so that the heat that storer 10 is produced when the running conducts to described radiating piece 30 rapidly, equably and distributes.Described radiating piece 30 comprises a radiating bottom plate that is rectangle 32 and some radiating fins 34 that is extended vertically upward by the top of radiating bottom plate 32.Form an air channel 36 between every two adjacent radiating fins 34, distinguished and admirable to guide.The top of described two heat-conducting plates 20 is by grafting material two ends combinations relative with the bottom of described radiating bottom plate 32 such as thermal grease or scolding tin, thereby exposes part outside a memory bank 40 at formation one receiving space 22 between two heat-conducting plates 20 and the radiating bottom plate 32 to the open air to accommodate storer 10.Described two heat-conducting plates, 20 parallel settings.The height of described receiving space 22 equals the height that described storer 10 is exposed to the part outside the described memory bank 40.Distance between the inboard heat-conducting medium of described two heat-conducting plates 20 just equals the thickness of described storer 10.Distance between two lateral surfaces of described two heat-conducting plates 20 equal the to peg graft width of described memory bank 40 forms passage to peg graft at a plurality of storeies 10 with a plurality of memory bank 40 (please refer to Fig. 3) back and guides the cold wind that described storer 10 is dispelled the heat to flow into described passage described storer 10 is dispelled the heat between two adjacent heat abstractors 100.In the present embodiment, the height of described radiating fin 34 is 2 millimeters, interferes with other elements preventing, and can save the space.Described two heat-conducting plates 20 are aluminium sheet.In other real-time modes, the height of described radiating fin 34 can be adjusted according to the actual needs.The material of described two heat-conducting plates 20 also can be changed according to actual needs.

When using 100 pairs of described storeies 10 of described heat abstractor to dispel the heat, described heat abstractor 100 is covered on the storer 10 that is plugged on the described memory bank 40 from top to bottom, and described heat abstractor 100 just is exposed to described storer 10 described memory bank 40 outer parts and covers.Heat-conducting medium on two heat-conducting plates 20 of described heat abstractor 100 just is attached at the both sides of described storer 10.The heat that described storer 10 produces conducts to described radiating piece 30 through the heat-conducting medium of described two heat-conducting plates 20 both sides.When giving cold wind to storer 10, come described storer 10 is dispelled the heat in the cold wind air channel 36 that forms of just can flowing through between the two adjacent radiating fins 34.Simultaneously the cold wind passage that forms between the two adjacent heat abstractors 100 of also can flowing through comes described storer 10 is dispelled the heat.

By the heat radiation of the storer 10 that is equiped with described heat abstractor 100 is carried out radiating efficiency that analog simulation adopts 100 pairs of described storeies 10 of described heat abstractor to dispel the heat can to make described storer 10 as can be known promote about 17%, thereby solved the heat dissipation problem of described storer 10.

Claims (4)

1. storer heat abstractor, comprise two heat-conducting plates and a radiating piece that is connected with described two heat-conducting plates, described radiating piece comprises a radiating bottom plate and some radiating fins of being located on the described radiating bottom plate, form the distinguished and admirable air channel of a guiding between every two adjacent radiating fins, described two heat-conducting plates are arranged on the relative two ends of described radiating bottom plate, thereby the receiving space of described storer is accommodated in formation one between described two heat-conducting plates and described radiating bottom plate, the inboard heat-conducting medium that attaches of each heat-conducting plate, distance between the inboard heat-conducting medium of described two heat-conducting plates just equals the thickness of described storer, conducts to described radiating fin with the heat that is installed in the described storer in back on the described storer at described heat abstractor by described heat-conducting medium.

2. storer heat abstractor as claimed in claim 1 is characterized in that: the top of described two heat-conducting plates is by the thermal grease two ends combination relative with the bottom of described radiating bottom plate.

3. storer heat abstractor as claimed in claim 1 is characterized in that: the height of described radiating fin is 2 millimeters.

4. storer heat abstractor as claimed in claim 1 is characterized in that: equal the to peg graft width of memory bank of described storer of the distance between the described two heat-conducting plates outside.

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